Abisko: Deep codesign of an architecture for spiking neural networks using novel neuromorphic materials

IF 3.5 3区计算机科学 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

International Journal of High Performance Computing Applications Pub Date : 2023-06-22 DOI:10.1177/10943420231178537

J. Vetter, Prasanna Date, F. Fahim, Shruti R. Kulkarni, P. Maksymovych, A. Talin, Marc Gonzalez Tallada, Pruek Vanna-Iampikul, Aaron R. Young, David Brooks, Yu Cao, Wei Gu-Yeon, S. Lim, Frank Liu, Matthew J. Marinella, B. Sumpter, Narasinga Rao Miniskar

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引用次数: 1

Abstract

The Abisko project aims to develop an energy-efficient spiking neural network (SNN) computing architecture and software system capable of autonomous learning and operation. The SNN architecture explores novel neuromorphic devices that are based on resistive-switching materials, such as memristors and electrochemical RAM. Equally important, Abisko uses a deep codesign approach to pursue this goal by engaging experts from across the entire range of disciplines: materials, devices and circuits, architectures and integration, software, and algorithms. The key objectives of our Abisko project are threefold. First, we are designing an energy-optimized high-performance neuromorphic accelerator based on SNNs. This architecture is being designed as a chiplet that can be deployed in contemporary computer architectures and we are investigating novel neuromorphic materials to improve its design. Second, we are concurrently developing a productive software stack for the neuromorphic accelerator that will also be portable to other architectures, such as field-programmable gate arrays and GPUs. Third, we are creating a new deep codesign methodology and framework for developing clear interfaces, requirements, and metrics between each level of abstraction to enable the system design to be explored and implemented interchangeably with execution, measurement, a model, or simulation. As a motivating application for this codesign effort, we target the use of SNNs for an analog event detector for a high-energy physics sensor.

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Abisko：使用新型神经形态材料的尖峰神经网络架构的深度协同设计

Abisko项目旨在开发一种能够自主学习和操作的节能尖峰神经网络（SNN）计算架构和软件系统。SNN架构探索了基于电阻开关材料的新型神经形态器件，如忆阻器和电化学RAM。同样重要的是，Abisko采用深度代码设计方法，通过吸引来自整个学科的专家来实现这一目标：材料、设备和电路、架构和集成、软件和算法。Abisko项目的主要目标有三个。首先，我们正在设计一种基于SNNs的能量优化的高性能神经形态加速器。该架构被设计为一个可以部署在当代计算机架构中的小芯片，我们正在研究新型神经形态材料来改进其设计。其次，我们正在为神经形态加速器开发一个高效的软件堆栈，该堆栈也将可移植到其他架构，如现场可编程门阵列和GPU。第三，我们正在创建一种新的深度代码设计方法和框架，用于在每个抽象级别之间开发清晰的接口、需求和度量，以使系统设计能够与执行、测量、模型或模拟互换地探索和实现。作为这项代码设计工作的一个激励性应用，我们的目标是将SNN用于高能物理传感器的模拟事件检测器。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of High Performance Computing Applications 工程技术-计算机：跨学科应用

CiteScore

6.10

自引率

6.50%

发文量

审稿时长

>12 weeks

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